Renewable Energy Supply Chain Expansion Decisions-making Using AHP
Subject Areas : Expert Systems
Bader Al-Ablani
1
,
Marwa Mekky
2
,
Noura Al-Ghimlas
3
1 - Mechanical Engineering Department, Faculty of Engineering, Benha University, Cairo, Egypt
2 - Department of Mechanical Design and Production Engineering, Cairo University, Giza, Egypt
3 - Department of Quantitative Methods and Information Systems, College of Business Administration, Kuwait University, Kuwait
Keywords: Analytical Hierarchy Process (AHP), Multi criteria decision making, Renewable energy factors, Renewable Energy Supply Chain (RESC), Supply chain expansion decisions,
Abstract :
In this study the challenges facing wider use of renewable energy are investigated. Robust supply chain is a necessity for better coverage of energy provision. Renewable energy industry faces several challenges in production, delivery, and distribution. Hence, a multi criteria decision-making model is formulated to inspect the effect of industry attributes on the decisions taken to achieve balanced and wider coverage of the renewable energy supply chain. AHP framework is developed and used to decide between three alternatives that cover the challenging areas of the supply chain in order to achieve the goal of the study. Additionally, a questionnaire is completed by three experts in the energy field in the state of Kuwait to assess the priorities of the three alternatives with respect to the study goal. Results of the study provide a sight into the nature of the problem and decisions to be taken to expand the use of renewable energy sources over fossil fuel.
García-Olivares, A., Solé, j., Osychenko, O., Transportation in a 100% renewable energy system, Energy Conversion and Management 2018, 158: 266–285.
[2] Xie, F., Modeling sustainability in renewable energy supply chain systems, PhD, Clemson University South Carolina, United States, 2014.
[3] Report on electrical power generation from renewable energy in State of Kuwait, Kuwait foundation for the advancement of sciences, 2010.
[4] Gastli, A., San Miguel Armendáriz, J., Challenges Facing Grid Integration of Renewable Energy in the GCC Region, EU-GCC Renewable Energy Policy Experts’ Workshop, 2013, in Abu Dhabi, UAE.
[5] Komor, P., Molnar, T., Background paper on distributed renewable energy generation and integration, Bonn, Germany, Technology Executive Committee (TEC), United Nations Framework Convention on Climate Change (UNFCCC), 2015.
[6] Goentzel, J., Renewable energy supply chains: delivering on the promise of green energy, The Center for Transportation & Logistics, 2009.
[7] Sprick, S., Grieger, M., Werner, A., Renewable energy supply chain management in the context of Virtual Power Systems, IECON 2013 - 39th Annual Conference of the IEEE Industrial Electronics Society, 2013, Vienna, Austria, pp. 4785 – 4790, DOI:10.1109/IECON.2013.6699909
[8] Fernando, Y., Yahya, S., Challenges in implementing renewable energy supply chain in service economy era, Procedia Manufacturing 2015, 4: 454 – 460.
[9] Ahmad Gondal, I., Offshore Renewable energy resources and their potential in a green Hydrogen supply chain through power-to-gas, Sustainable Energy & Fuels 2019, 3, 1468-1489, DOI: 10.1039/C8SE00544C
[10] Member companies of the Hydrogen Council, How hydrogen empowers the energy transition, Hydrogen Council, January 2017.
[11] Andrew Walker, H., Renewable energy delivery systems and methods, United States Patent, Patent No.: US 8,604,641 B2, 2013.
[12] L. Saaty, T., Decision Making – The Analytic Hierarchy And Network Processes (AHP/ANP), Journal Of Systems Science And Systems Engineering, March 2004, 13(1): 1-35.
[13] Mastrocinque, E., Javier Ramírez, F., Honrubia-Escribano, A., T. Pham, D., An AHP-based multi-criteria model for sustainable supply chain development in the renewable energy sector, Expert Systems With Applications 2020, 150: 113321.
[14] Robles Algarín, C., Polo Llanos, A., Ospino Castro, A., An Analytic Hierarchy Process Based Approach for Evaluating Renewable Energy Sources, International Journal of Energy Economics and Policy 2017, 7(4): 38-47.
[15] Budak, G., Chen, X., Celik, S., Ozturk, B., A systematic approach for assessment of renewable energy using analytic hierarchy process, Energy, Sustainability, and Society 2019, 9:37.
[16] Luo, L., Yang, L., Mohd Hana_ah, M., Construction of renewable energy supply chain model based on LCA, Journal of Open Physics 2018, De Gruyter, 16:1118–1126, https://doi.org/10.1515/phys-2018-0132.
[17] World Energy Assessment: Energy and the challenge of sustainability, 2000.
[18] Renewable energy legislations and policies in the Arab region–fact sheet, United Nations, ESCWA, 2019.
[19] A. Fahmy, S., M. Mohamed, M., F. Abdelmaguid, T., Multi-layer dynamic facility location-allocation in supply chain network design with inventory, and CODP positioning decisions, The 9th International Conference on Informatics and Systems-Operations Research and Decision Support Track (INFOS2014), 2014, Egypt, pp. 15-17.
[20] Salvendy, G., Handbook of Industrial Engineering: Technology and Operations Management, Third Edition, New York City, United States, John Wiley & Sons, Inc, 2001.
[21] Ilo, A., The Energy Supply Chain Net, Energy and Power Engineering 2013, 5: 384-390.
[22] Mekky M., M., Multi-layer dynamic facility location allocation in supply chain network design with inventory, and CODP positioning decisions, MSc, Faculty of Engineering at Cairo University, Giza, Egypt, 2016.
[23] Ricardo Saavedra M., M., Hora de O. Fontes, C., Gaudêncio M. Freires, F., Sustainable and renewable energy supply chain: A system dynamics Overview, Renewable and Sustainable Energy Reviews 2018, 82: 247–259.
[24] N. Zatsarinnaya, Y., G. Logacheva, A., N. Gainullin, R., F. Alekseeva, S., I. Amirov, D., Solution for renewable future, International Scientific and Technical Conference on Smart Energy Systems (SES-2019), 2019, E3S Web of Conferences, Kazan, Russia, 124: 04010.
[25] Renewable Energy Integration in Power Grids, Technology Brief of The International Renewable Energy Agency (IRENA), and The Energy Technology Systems Analysis Programme (ETSAP), 2015.
[26] Le Pira, M., Inturri, G., Ignaccolo, M., Pluchino, A., Modelling consensus building in Delphi practices for participated transport planning, Transportation Research Procedia, 2017, 25, pp.3725–3735.
[27] D. Goepel, K., BPMSG’s AHP Online System, Business Performance Management Singapore.
[28] The hydrogen economy starts today, MEA Energy Week 2020, Siemens-Energy press.
